KR200223114Y1 - A structure reinforcing for retaining wall for inclined plane which to cut off a rock wall - Google Patents

Abstract

The present invention utilizes EPS blocks and geogrids that are effectively used as lightweight fill materials for roads and shifts. A retaining wall reinforcement structure for cut slopes.

In other words, the present invention is to install the geogrid (3) at a predetermined interval between the front block (1) and the rear surface of the front block (1) and the slope of the retaining wall stacked at a predetermined distance from the slope of the retaining wall to fill the fill with backfill material. In the retaining wall reinforcement structure having the arm cut slope 4 which is difficult to apply the general retaining wall reinforcement structure, the EPS block 5 in the form of an inverted triangle from the bottom to the top along the rear surface of the front block 1; The lamination is carried out while the geogrid 3 is disposed at regular intervals between the EPS block 5 and the slope of the retaining wall, and a backfill material is filled to form a fill layer 2, thereby filling the backfill material. The front part of the fill layer 2 is formed to be inclined surface (6).

Description

A structure reinforcing for retaining wall for inclined plane which to cut off a rock wall}

The present invention relates to a retaining wall reinforcement structure for rock cutting slopes, and more specifically, an arm that is a problem of an existing block-type reinforcement soil retaining wall using EPS blocks and geogrids that are effectively utilized as lightweight fill materials for roads and shifts. The present invention relates to a retaining wall reinforcement structure for cancer cut slopes to compensate for the difficulty of laying the geogrid at the cut slope and the deterioration of workability.

In general, cut slopes exist mostly in sites (apartment complexes) or roads that are flattened by cutting mountains and hills.

Since the cut slope is formed by artificial cutting work, the slope is easily lost and unbalanced. Also, because the cohesiveness of the soil is weak, the slope is easily broken when it rains a lot or causes a situation. By building the sediment, etc. are prevented from being lost or happening.

To this end, as a plan for reinforcing slopes (or slopes), reinforced concrete retaining walls have been used in Korea, and the reinforced concrete structures are not only costly and time-consuming for forming and curing, but also for excavation and fill work. It costs a lot of construction cost, and also has the disadvantage that there are many restrictions on large-scale cutting work.

Recently, the reinforced earth retaining wall has been constructed in two types.

One is to connect the concrete panel to the retaining wall, and connect the strip of polyethylene material (PET) to the connecting ring installed on the back of the concrete panel. The end of the belt is fixed with a wedge-shaped anchor.

Another method is to bind geogrids, which are civil fibers, between the upper and lower blocks, and install the geogrids on the backfill reinforcement section to integrate the block and backfill reinforcement sections.

Meanwhile, referring to the retaining wall reinforcement structure using the geogrid, as shown in FIG. 1, the front block 10 is stacked on the concrete foundation on the front of the cut slope 40, and then the front block 10 and the cut slope ( 40) to form a fill layer 20 by filling with a backfill material such as crushed stone (60) or earth and sand, at this time, geogrid 30 is a geo-fiber material with a certain layer to reinforce the fill layer (20) It is intended to be inserted.

Here, the geogrid 30 is used as a reinforcing material for civil engineering and construction, such as ground reinforcement, ground treatment, soil reinforcement before concrete treatment, shielding for construction, etc. The conventional geogrid is a general-purpose plastic (polyester, polypropylene, etc.) It is common to manufacture.

In addition, when the retaining wall is constructed as described above, as shown in FIG. 2, the cutting slope 40 and the front block 10 are constructed in a substantially rectangular shape in principle.

This is due to the shear (friction) resistance of the front block 10, the shear force of the crushed stone 60 inserted into the back of the front block 10, and the horizontal direction of the geogrid 30 against the vertical stress due to the earth pressure of the fill layer 20. This is because it is most preferable to maintain the rectangular shape in consideration of the resistance against.

Here, in the drawings, reference numeral 50 denotes a concrete foundation.

On the other hand, in the case where the cut slope 40 is made of a rock wall and the slope is a cancer cut slope that is inclined at an angle more obliquely than shown in FIG. 2, the retaining wall made of the laminated front block 10 in front of the arm cut slope is formed. When constructing and reinforcing the retaining wall through the reinforcement structure using only the geogrid 30, the bottom rock of the cancer cutting slope is excavated to maintain a substantially rectangular shape between the arm cutting slope and the front block 10. The load can be balanced.

In this case, as the above-described difficulty of working to excavate the bottom of the rock has been followed, conventionally, the above-described cancer cutting slopes could not be implemented in the reinforcement structure using only geogrid.

In other words, in the case of constructing a laminated retaining wall in close proximity to the construction of the rectangular shape as well as the construction of the slope that requires the retaining wall is inadequate, there is no special support means of the retaining wall reinforcing member In addition, since the vertical stress due to the filling layer filled with the backfill material takes the form of an inverted triangle is difficult to balance only by the resistance of the geogrid, the conventional construction of the laminated retaining wall using the geogrid has not been performed.

As such, the amount of construction of the front block type reinforced earth retaining wall is increasing day by day. However, due to the domestic construction conditions, construction sites that are difficult to install the above-mentioned square type reinforcement materials are frequently generated due to underground structures such as rock or apartment structures. Effective supplementation is required.

Therefore, when the retaining wall is constructed in close proximity to a rock cutting slope requiring the retaining wall in the related art, the reinforced concrete retaining wall due to the formwork has to be poured in the field.

In addition, the concrete retaining wall constructed as described above may be collapsed due to the earth pressure of the backfill material and the weighting pressure of the infiltrating water permeating into it. The retaining force of the steel bar was reinforced to support the concrete retaining wall.

However, the conventional concrete retaining wall construction method requires many work processes such as formwork installation, reinforcement, concrete placing, concrete curing, anchor hole drilling, steel rod fixing, steel rod fixing condition check, and binding with concrete retaining wall. There is a problem that the process is complicated and takes a lot of time, labor, and expenses.

The present invention was devised to improve the problems of the concrete retaining wall in the above-mentioned rock cutting slope and the problem that the retaining wall reinforcement structure using the geogrid cannot be constructed in the section where the back length of the reinforcement soil retaining wall is difficult to install in the rock cutting slope. Its purpose is to provide a retaining wall reinforcement structure for rock cutouts that can be used efficiently in construction sites where it is difficult to install rectangular reinforcements such as arm cutting slopes by using ultra lightweight EPS blocks and geogrids. .

1 is a partial cutaway perspective view showing a retaining wall reinforcement structure using a conventional geogrid.

Figure 2 is a side cross-sectional view showing a retaining wall reinforcement structure using a conventional geogrid.

Figure 3 is a side cross-sectional view showing a retaining wall reinforcement structure using EPPS block and geogrid according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: front block 2: fill layer

3: geogrid 4: cancer cutting slope

5: EPS block 6: law surface

7: concrete foundation

The present invention for achieving the object as described above is a general block to be filled with backfill material while laying the geogrid at regular intervals between the front block and the rear surface of the front block and the slope of the retaining wall are stacked at a certain distance from the slope of the retaining wall. In the retaining wall reinforcement structure having a rock cut slope that is difficult to apply the retaining wall reinforcement structure, an EPS block is stacked in an inverted triangle form from the lower side to the upper side along the rear surface of the front block, and the EPS block After filling the geogrid between the slopes of the retaining wall and at regular intervals, the backfill material is filled, thereby providing a retaining wall reinforcement structure for the cut-off slopes so that the front portion of the backfill material is formed into an inclined surface.

In this case, the EP block is made of EPs (Expanded Poly-Styrene), which is a porous lightweight material, commonly referred to as 'footfoschiropole' as a block.

Therefore, the PS block not only reduces its own load but also distributes and supports the load of the fill layer accumulated on the side part, thereby reducing the load burden on the front block, and excellent drainage, contributing to the stability of the construction. Done.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

At this time, the same name as for the same components as the prior art to the retaining wall reinforcement structure according to the present invention described in the embodiment and the detailed description thereof will be omitted.

3 is a side cross-sectional view showing a retaining wall reinforcement structure using an EPS block and a geogrid according to the present invention.

In the retaining wall reinforcement structure according to the present invention, as shown in FIG. 3, the front block 1 is stacked on the concrete foundation 7 in close proximity to the female cutout surface 4 to be constructed in the form of a retaining wall. (1) EPS blocks (5) are stacked in the form of an inverted triangle along the back surface, and the geogrid (3) and the soil layer (2) using earth and sand are formed to the rear of the ESP blocks (5). It is a structure formed.

Here, as the ES block 5 takes the form of an inverted triangle along the rear surface of the front block 1, the front portion of the fill layer 2 that is directly deposited behind the ES block 5 is the front surface (6). ).

Therefore, when the front part of the fill layer 2 forms the normal surface 6, the load of the fill layer 2 acting on the front block 1 is in a rectangular shape, and the vertical load is higher than when the backfill material is filled. It is much smaller, which greatly reduces the load burden.

In particular, the ES block 5 is made of EPS (Expanded Poly-Styrene), a porous lightweight material commonly referred to as 'balfoschiropol', the self-load of the ES block (5) As the load is applied to the front block 1, the load burden on the front block 1 is reduced, and the PS block 5 distributes and supports the load of the fill layer 2 accumulated on the side surface, thereby greatly increasing the load burden on the front block 1. As it can be reduced, it contributes to the stability of the construction (retaining wall).

In addition, when the geogrid (3) is installed as described above, even if the geogrid (3) is installed only in the fill layer (2), a sufficient horizontal resistance can be secured, but in order to secure the stability of the retaining wall It is preferable to extend the geogrid 3 to the block 1.

At this time, the construction height of the PS block 5 disposed on the rear surface of the front block 1, and the construction height of the fill layer (2) to be filled and compacted by earth and sand from the rear of the EP block 5 is the same It is constructed sequentially in height.

As such, the present invention is preferably applied to the case where the retaining wall should be approached at a difficult site in the rectangular shape, as described above, since the slope is inclined obliquely as in the above-mentioned arm cutting slope 4.

In particular, when the rear length of the front block 5 is short and the geogrid 3 alone cannot maintain sufficient reinforcement strength, the PS block 5, which is a super lightweight material, is disposed on the back of the front block 1 as in the present invention. It is important to reduce the burden and ensure stability.

In addition, according to the present invention, since the PS block 5 replaces the construction of putting the crushed stone 60 in order to give a horizontal shear force to the rear surface of the conventional front block 1, the amount of natural aggregate such as the crushed stone 60 is used. Not only can it be reduced, but also economical to use the EPS (EPS) material that is more competitive in cost than the crushed stone (60).

As described above, according to the present invention, it is possible to lay the geogrid using the EP block in the construction site of the retaining wall difficult to install the existing reinforcement soil retaining wall or the retaining wall construction site difficult to install the geogrid, the conventional rock cutting slope It can replace the concrete retaining wall used in the close construction at, so it can not only make economical design but also greatly improve the workability.

In particular, the present invention has very good characteristics of manpower construction and workability due to the light weight of EPS material.

Claims (2)

Retaining wall with a front block that is stacked at a certain distance from the cutting slope, and a rock cutout that is difficult to apply a general retaining wall reinforcement structure that is laid with a backfill while laying a geogrid at regular intervals between the rear of the front block and the slope of the retaining wall. In the reinforcement structure, EPS (EPS) blocks are stacked in an inverted triangle form from the bottom to the top along the rear surface of the front block, and the filling material is filled while laying the geogrid at regular intervals between the EPS blocks and the slope of the retaining wall. A fill layer is formed, and thus the front wall of the fill layer in which the backfill material is filled is formed in a sloped slope surface, the retaining wall reinforcement structure for rock cutting. The method of claim 1, Reinforcing wall retaining structure for rock cutting slopes, characterized in that the geogrid is installed in the backfill material at regular intervals to extend to the laminated surface of the PS block.